An internal combustion engine may include an engine block, a cylinder defining at least one combustion chamber, and a piston in the cylinder. The piston may travel in a first stroke from one end to an opposite end of the cylinder, and may be sized relative to the cylinder to enable an expansion stroke portion of the first stroke while the piston travels under gas expansion pressure, and a momentum stroke portion of the first stroke for the remainder of the first stroke following the expansion stroke portion. A passageway may be formed in the piston rod to communicate gas flow between a first combustion chamber and an area external to the cylinder when the piston is in a first position, and to communicate gas flow between a second combustion chamber and an area external to the cylinder when the piston is in a second position.
|
3. An engine, comprising:
a cylinder having a first combustion chamber at a first end of the cylinder and a second combustion chamber at an opposing second end of the cylinder;
a piston slidably mounted within the cylinder;
a piston rod having a passageway extending through the piston into both the first and second combustion chambers;
at least one first opening in a first side of the piston rod configured to move into and out of the first combustion chamber to selectively communicate gas to the first combustion chamber; and
at least one second opening in a second side of the piston rod configured to move into and out of the second combustion chamber to selectively communicate gas to the second combustion chamber,
wherein the piston rod includes an open end, and the piston rod is configured to supply the first combustion chamber or the second combustion chamber with gas via the open end.
1. A piston assembly, comprising:
a piston configured to be slidably mounted within a cylinder having a first combustion chamber at a first end and a second combustion chamber at an opposing second end;
a piston rod having an interconnecting flow passageway extending through the piston;
at least one first opening in a first side of the piston rod configured to move into and out of the first combustion chamber to selectively communicate gas to the first combustion chamber; and
at least one second opening in a second side of the piston rod configured to move into and out of the second combustion chamber to selectively communicate gas to the second combustion chamber,
wherein the piston is configured such that when the first opening is outside the first combustion chamber the second opening is inside the second combustion chamber, and when the first opening is inside the first combustion chamber the second opening is outside the second combustion chamber.
2. An engine, comprising:
a cylinder having a first combustion chamber at a first end of the cylinder and a second combustion chamber at an opposing second end of the cylinder;
a piston slidably mounted within the cylinder;
a piston rod having a passageway extending through the piston into both the first and second combustion chambers;
at least one first opening in a first side of the piston rod configured to move into and out of the first combustion chamber to selectively communicate gas to the first combustion chamber; and
at least one second opening in a second side of the piston rod configured to move into and out of the second combustion chamber to selectively communicate gas to the second combustion chamber,
wherein the piston is slidable between a first position where the first opening is outside the first combustion chamber and the second opening is inside the second combustion chamber, and a second position where the first opening is inside the first combustion chamber and the second opening is outside the second combustion chamber, and
wherein the passageway connects a first passageway in the piston rod on a first side of the piston to a second passageway in the piston rod on a second side of the piston.
4. The engine of
the passageway is configured to communicate gas flow in a first direction from the first side of the piston through the passageway and through the second opening to the second combustion chamber on an opposite side of the piston, and to communicate gas flow in a second direction, opposite the first direction, from the second side of the piston through the passageway and through the first opening to the first combustion chamber on the first side of the piston.
5. The engine of
the passageway is configured to communicate gas flow in a first direction in the first position from the first side of the piston through the passageway and through the second opening to the second combustion chamber on an opposite side of the piston, and to communicate gas flow in the first direction in the second position through the passageway and through the first opening to the first combustion chamber.
6. The engine of
8. The engine of
10. The engine of
11. The engine of
12. The engine of
13. The engine of
14. The engine of
15. The engine of
wherein the piston is slidable between a first position where the first opening is outside the first combustion chamber and the second opening is inside the second combustion chamber, and a second position where the first opening is inside the first combustion chamber and the second opening is outside the second combustion chamber,
the piston is slidable to a third position where both the first opening and the second opening are blocked to enable a pressure buildup in the passageway, and
the pressure buildup is released into the cylinder at the first position or the second position.
16. The engine of
17. The engine of
20. The engine of
|
This application is a continuation application of and claims the benefit of priority from U.S. patent application Ser. No. 16/207,479, filed Dec. 3, 2018, entitled “Piston Rod and Free Piston Engine,” the contents of which is incorporated herein by reference in its entirety.
The present disclosure relates to the field of internal combustion engines, and more particularly to the field of internal combustion engines having a free piston.
Internal combustion engines are known. The most common types of piston engines are two-stroke engines and four-stroke engines. These types of engines include a relatively large number of parts, and require numerous auxiliary systems, e.g., lubricant systems, cooling systems, intake and exhaust valve control systems, and the like, for proper functioning.
Some embodiments may relate to a linear reciprocating engine. The linear reciprocating engine may include an internal combustion engine. The internal combustion engine may include a cylinder having a first combustion chamber at a first end thereof and a second combustion chamber at an opposing second end thereof, a piston slidably mounted within the cylinder, and a piston rod having a passageway extending through the piston into both combustion chambers. There may be provided at least one first opening in a first side of the piston rod configured to move into and out of the first combustion chamber to selectively communicate gas to the first combustion chamber, and at least one second opening in a second side of the piston rod configured to move into and out of the second combustion chamber to selectively communicate gas to the second combustion chamber. The piston may be slidable between a first position where the first opening is outside the first combustion chamber and the second opening is inside the second combustion chamber, and a second position where the first opening is inside the first combustion chamber and the second opening is outside the second combustion chamber.
According to some embodiments, an engine may be provided that enables gas to be communicated to each of two combustion chambers at separate times. Gas may be constantly supplied to flow through the passageway in the piston rod, while the gas is allowed to enter the cylinder only when an opening among the first openings and second opening is in communication with the cylinder. The first opening may include one or more openings, and the second opening may include one or more openings. Gas may travel through the piston rod to supply both of the combustion chambers appropriately during the various phases of the stroke of the engine.
Exemplary advantages and effects of the present invention will become apparent from the following description taken in conjunction with the accompanying drawings wherein certain embodiments are set forth by way of illustration and example. The examples described herein are just a few exemplary aspects of the disclosure. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention.
The present disclosure relates to internal combustion engines. While the present disclosure provides examples of free piston engines, it should be noted that aspects of the disclosure in their broadest sense, are not limited to a free piston engine. Rather, it is contemplated that the forgoing principles may be applied to other internal combustion engines as well.
As used herein, unless specifically stated otherwise, the term “or” encompasses all possible combinations, except where infeasible. For example, if it is stated that a component includes A or B, then, unless specifically stated otherwise or infeasible, the component may include A, or B, or A and B. As a second example, if it is stated that a component includes A, B, or C, then, unless specifically stated otherwise or infeasible, the component may include A, or B, or C, or A and B, or A and C, or B and C, or A and B and C.
An internal combustion engine in accordance with the present disclosure may include an engine block. The term “engine block,” also used synonymously with the term “cylinder block,” may include an integrated structure that includes at least one cylinder housing a piston. In the case of a free piston engine block, the engine block may include a single cylinder, or it may include multiple cylinders.
In accordance with the present disclosure, a cylinder may define at least one combustion chamber in the engine block. In some internal combustion engines in accordance with the present disclosure, a combustion chamber may be located on a single side of a cylinder within an engine block. In some internal combustion engines in accordance with the present disclosure, the internal combustion engine may include two combustion chambers, one on each side of a cylinder within an engine block.
Embodiments of the present disclosure may further include a piston in the cylinder. In accordance with some embodiments of the disclosure used in a free piston engine, the piston may include two heads on opposite sides. In some embodiments, the piston may be considered to be “slidably mounted” in the cylinder. This refers to the fact that the piston may slide through a plurality of positions in the cylinder from one side of the cylinder to the other. While the present disclosure describes piston examples, the invention in its broadest sense is not limited to a particular piston configuration or construction.
By way of example, as shown in
Cylinder 12 may include a first combustion chamber 71 and a second combustion chamber 73 (see
Reference is now made to
Cylinder 12 may include a peripheral cylinder wall 13 and exhaust ports 18 in peripheral cylinder wall 13. In some embodiments, exhaust ports 18 may consist of a single port. Exhaust ports 18 may be connected to an exhaust manifold configured for receiving exhaust gases or other gases from the combustion chambers and directing the gases away from the cylinder for exhaust aftertreatment. In the manner discussed above, for example, a passageway of the piston rod may be configured to introduce gas into a combustion chamber from a location outside the cylinder. Also, gases may exit the cylinder through an exhaust port, such as exhaust ports 18. In an embodiment, areas 65 and 67 external to cylinder 12 may simply refer to any region on an opposite side of a cylinder head 14, 15 from cylinder 12, regardless of whether the region is in direct contact with a cylinder head. In some embodiments, other ports may be provided to introduce gases from a manifold or other source located alongside the cylinder, rather than at ends of the cylinder. Thus, in a general sense, locations outside the cylinder may be at the ends of the cylinder, alongside the cylinder, or a combination of both, for example.
In accordance with embodiments of the disclosure, a piston rod may include a passageway configured to communicate gas flow between at least one combustion chamber and an area external to the cylinder. As used herein, the term “passageway” can be defined by any structure or void capable of communicating gas flow. It may include, for example, a channel or conduit completely or partially contained within at least part of the piston rod portion.
For example, in some exemplary embodiments of an engine according to the disclosure, the passageway in the piston rod may render piston rod 40, including piston rod portions 42 and 43, at least partially hollow. In some embodiments, the passageway may extend completely through piston 50. An opening may be formed in one or each piston rod portion that may be in fluid communication with the passageway of the piston rod, to thereby permit fluid to enter or exit the passageway through the opening. It is understood that a “fluid” may include gas, such as air. As shown in
By way of example with reference to
As illustrated in
Piston rod 40 may include at least one first opening, such as first opening 44 in a first side of piston rod 40, and at least one second opening, such as second opening 48 in a second side of piston rod 40, the second side being opposite the first side. In one exemplary embodiment, as shown in
A wall thickness of piston rod 40 may be varied along axis A. For example, as shown in
Piston rod 40, together with piston 50, may be configured to move in a linear reciprocating motion in cylinder 12. Piston 50 may be configured to slide within cylinder 12 past a plurality of positions. Due to back and forth motion of piston rod 40, first opening 44 and second opening 48 may selectively communicate fluid flow from outside cylinder 12 to inside cylinder 12. First opening 44 may be arranged on piston rod 40 such that first opening 44 is configured to move into and out of first combustion chamber 71 to selectively communicate gas to first combustion chamber 71. Similarly, second opening 48 may be arranged on piston rod 40 such that second opening 48 is configured to move into and out of second combustion chamber 73 to selectively communicate gas to second combustion chamber 73.
In accordance with some embodiments of the disclosure, sliding action of the piston may enable gases to be introduced into cylinder 12, while gases on opposite sides of piston 50 may be prevented from being exchanged with one another. For example, a piston ring circumscribing piston 50 may prevent leakage of compressed gases past piston 50.
In some embodiments, the cylinder head on each side of the engine block may include (e.g., be connected to or integrally formed with) an intake manifold (not shown). In some embodiments, only one cylinder head may include an intake manifold. Passageway 46 may be configured to communicate gas flow between first combustion chamber 71 and the intake manifold at the first end of cylinder 12 when piston 50 is in a first position. Furthermore, passageway 46 may be configured to communicate gas flow between second combustion chamber 73 and the intake manifold when piston 50 is in a second position. Thus, for example, with reference to
A cylinder in accordance with embodiments of the disclosure may be closed at both ends. For example, cylinder 12 of engine 10 may be closed at both ends thereof by cylinder heads 14 and 15, which may be connected to the cylinder 12 by a plurality of fasteners. As used herein, the term “closed” does not require complete closure. For example, despite that the cylinder heads may have openings therein through which piston rod 40 passes, the cylinder heads are still considered “closed” within the meaning of this disclosure.
In some embodiments, a peripheral portion of cylinder 12 may be provided with cooling fins (not shown). Alternative configurations of the engine 10 may include other external or internal features that assist with the cooling of the cylinder, such as water passageways formed internally within the cylinder walls or jacketing at least portions of the cylinder walls for water cooling, and other configurations of cooling fins or other conductive or convective heat transfer enhancement features positioned along the exterior of a cylinder peripheral wall to facilitate fluid cooling of the cylinder. Engine block 8 may include fluid passage 21 that may be used for circulating cooling water to a peripheral sidewall of cylinder 12. Fluid passage 21 may communicate with fluid port 5 (see
In accordance with exemplary embodiments of the disclosure, peripheral wall 13 of cylinder 12 may include at least one exhaust port between ends of cylinder 12. By way of example only, cylinder 12 may include an exhaust port 18 in a peripheral side wall of cylinder 12 between first cylinder head 14 and second cylinder head 15, the first and second cylinder heads 14, 15 being positioned at ends of the cylinder. In the exemplary embodiment illustrated in
In accordance with some exemplary embodiments of the disclosure, one or more exhaust ports 18 may be configured to communicate gas flow between the first combustion chamber and outside the cylinder when piston 50 is on the second combustion chamber side of the one or more exhaust ports 18, and may be configured to communicate gas flow between the second combustion chamber and outside the cylinder when the piston is on the first combustion chamber side of the one or more exhaust ports 18. By way of example only, this can occur when, as illustrated in
With reference to
In some embodiments, an inlet chamber 32 may be provided for allowing inlet air to enter engine 10. For example, as illustrated in
Supplying air from one end of engine 10 through inlet chamber 32 may provide a number of benefits. For example, air may be directed to flow into engine 10 substantially in a direction parallel to axis A, which may be in a longitudinal direction of engine 10. Piston rod 40 may include opening 45 and passageway 46, which is arranged to extend substantially along axis A, and thus, air may flow through piston rod 40 with less turbulence, which may reduce pressure losses. Furthermore, regions of stagnation may be minimized. As compared with providing air entering through side opening 33, for example, providing inlet chamber 32 may result in improved flow characteristics.
Air may be introduced into engine 10 through a vestibule among first vestibule 30 and second vestibule 31. Air may be configured to flow from area 65 or area 67 (external to cylinder 12) to an interior of cylinder 12, including first combustion chamber 71 or second combustion chamber 73. Air may be introduced into engine 10 through inlet chamber 32 via a vestibule among first vestibule 30 and second vestibule 31. For example, when piston 50 is in the first position, air may travel through inlet opening 29, and then air may be in communication with area 65, passageway 46, and second combustion chamber 73, as shown in
Engine 10 may include a first isolation area on one side of cylinder 12 and a second isolation area on an opposite side of cylinder 12. The first isolation area may include area 65, and the second isolation area may include area 67. The first and second isolation areas may be configured to isolate non-active piston rod parts during alternate cylinder charges. For example, when piston 50 is in the first position, air may travel from inlet opening 29, through passageway 46, and into second combustion chamber 73, as shown in
Air may be supplied to engine 10 through a single air supply. The air supply may be flow-connected to passageway 46 in piston rod 40 such that gas flow is communicated between first combustion chamber 71 and the air supply when piston 50 is in the first position. Furthermore, passageway 46 may be configured to communicate gas flow between second combustion chamber 73 and the air supply when piston 50 is in a second position. It is understood that air may be introduced into engine 10 by openings other than inlet opening 29. For example, air may be introduced via one or more of side openings 33. Air may be introduced through side opening 33 in first vestibule 30 while other openings (such as inlet opening 29) are sealed off. Thus, gas may be delivered from first vestibule 30 to cylinder 12. Alternatively, air may be introduced through side opening 33 in second vestibule 31 while other openings are sealed off. Side opening 33 may be configured such that air is directed to flow into engine 10 substantially in a direction perpendicular to axis A. Side opening 33 may be configured to direct gases into passageway 46 substantially through first opening 44, or through second opening 48. Configuring openings to introduce air into engine 10 by way of, e.g., inlet opening 29, or side opening 33, may allow design flexibility in consideration of packaging constraints. For example, in some embodiments, when air is introduced through inlet opening 29, engine 10 may be packaged into a long, thin space. In other embodiments, when air is introduced through side opening 33, engine 10 may be packaged into a short, compact space.
In some embodiments, both first vestibule 30 and second vestibule 31 may be configured to supply air to engine 10. For example, both side opening 33, provided on first vestibule 30, and side opening 33, provided on second vestibule 31, may be opened. The single air supply may supply air to both first vestibule 30 and second vestibule 31.
Each of the cylinder heads 14, 15 may further include an injector 34 (see
A double-faced piston consistent with embodiments of the present disclosure may be configured to travel in a first stroke from a first end of the cylinder to an opposite second end of the cylinder, and in a second stroke from the second end of the cylinder back to the first end. This length of travel is illustrated, by way of example, in
Piston 50 may be slidable between a plurality of positions throughout cylinder 12. For example, piston 50 may be slidable between a first position and a second position. The first position may be a position where first opening 44 is outside cylinder 12 and second opening 48 is inside cylinder 12. At the first position, second opening 48 may be inside the second combustion chamber of cylinder 12. The second position may be a position where first opening 44 is inside cylinder 12 and second opening 48 is outside cylinder 12. At the second position, first opening 44 may be inside the first combustion chamber of cylinder 12. The first position may correspond to the beginning of a first stroke of engine, and the second position may correspond to the end of the first stroke.
According to various exemplary embodiments of the present disclosure, the piston may be sized relative to the cylinder to enable an expansion stroke portion of each stroke wherein the piston travels under gas expansion pressure, and a momentum stroke portion of each stroke for the remainder of the stroke following the expansion stroke portion. The expansion stroke portion of each of the first and second strokes of the piston is the portion of travel when the piston directly moves under the expansion pressure of combustion. For example, the expansion portion of a stroke may be defined as the portion from a combustion position of the piston at each end of the cylinder to the point at which exhaust gases may be exchanged between the combustion chamber in which ignition of combustion gases (including air and fuel) has just occurred and an area external to the cylinder. In some embodiments, the termination of the expansion stroke portion may coincide with a position where the piston begins to expose an exhaust port.
At the combustion position of the piston during each stroke, a clearance volume may remain between each of the opposite faces of the piston and a respective end of the cylinder as closed off by the cylinder heads 14, 15. The combustion gases that are introduced into the combustion chamber before the piston reaches the combustion position may be compressed into the remaining clearance volume on that side of the piston between the piston face and the fire deck of the cylinder head. The compressed gasses in the clearance volume may be compressed into such a small volume that gas pressure prevents piston 50 from contacting a respective one of cylinder heads 14, 15. The compressed gases, which in some embodiments may include a fuel/air mixture, may be ignited by either a spark, or by self-ignition resulting at least in part from the compression of the combustion gases.
The combustion position may be a point along axis A corresponding to the beginning of a combustion event in cylinder 12. The combustion position may be a point where a predetermined compression ratio of gases in a combustion chamber is reached. For example, the combustion position may be a point where a compression ratio of a combustion chamber reaches 10:1. Combustion may be initiated at the combustion position by activating spark plug 38. The combustion position may be a point where piston 50 changes direction. The combustion position may be a zero-speed position of piston 50. In some embodiments, engine 10 may be configured so that piston 50 decelerates to zero-speed at the moment that combustion is initiated. The combustion position may correspond to the first position mentioned above, which may correspond to the beginning of the first stroke of engine 10. In some embodiments, the combustion position may be a fixed position. However, it will be understood that the combustion position may be a variable position that may be determined, for example, by when spark plug 38 is activated, or when auto-ignition is configured to occur.
The expansion stroke portion of each stroke occurs after the ignition of the compressed combustion gases as chemical energy from the combustion in each combustion chamber is converted into kinetic energy (e.g., mechanical work) of the piston. Simultaneously with the expansion stroke portion of each stroke on one side of the piston, gas flow may occur for at least a portion of the expansion stroke portion between the combustion chamber on the opposite side of the piston and the intake manifold at the opposite end of the cylinder, as well as through exhaust ports.
In some embodiments, useful work may be extracted from engine 10 by, for example, mechanically coupling one end of piston rod 40 to an output. Second piston rod portion 43 may be connected to an apparatus at an end opposite piston 50 that may be configured to convert reciprocating linear motion to useful work. For example, a linear actuator may be coupled to second piston rod portion 43 at opening 47 (see, e.g.,
Referring back to
As shown in
According to some embodiments, a length (in axial direction A) of piston 50, a length of cylinder 12, a location of exhaust ports 18, and a location of first and second openings 44, 48 in first and second piston rod portions 42, 43 may be arranged such that when piston 50 is in a combustion phase in the first combustion chamber, piston 50 blocks exhaust ports 18 from communicating with the first combustion chamber and first opening 44 in first piston rod portion 42 is outside of the first combustion chamber, while simultaneously exhaust ports 18 are in fluid communication with the second combustion chamber, and second opening 48 in second piston rod portion 43 is within the second combustion chamber. This may be accomplished by various alternative structures. By way of example only with reference to the figures, the length of piston 50, the length of cylinder 12, the location of exhaust ports 18, and the location of openings 44 and 48 in each of first and second piston rod portions 42, 43 extending from opposite faces of piston 50 may be arranged such that when piston 50 is in a combustion phase in a first combustion chamber on one side of piston 50, piston 50 blocks exhaust ports 18 from communicating with the first combustion chamber. First opening 44 to the one side of piston 50 remains outside of the first combustion chamber, thereby preventing communication of gases between inlet chamber 32 on that one side of piston 50 and the first combustion chamber.
Simultaneously, exhaust ports 18 are in fluid communication with the second combustion chamber on the opposite side of piston 50, and second opening 48 in second piston rod portion 43 may be located within the second combustion chamber. Similarly, when piston 50 is in another combustion stage in the second combustion chamber on the opposite side, piston 50 blocks exhaust ports 18 from communicating with the second combustion chamber. Second opening 48 to the second side of piston 50 remains outside of the second combustion chamber, thereby preventing communication of gases between inlet chamber 32 on the second side of piston 50 and the second combustion chamber. Simultaneously, exhaust ports 18 are in fluid communication with the first combustion chamber on the first side of piston 50, and first opening 44 in first piston rod portion 42 may be located within the first combustion chamber.
According to some embodiments, the length of piston 50, a length of cylinder 12, a location of exhaust ports 18, and a location of first and second openings 44, 48 in first and second piston rod portions 42, 43 may be arranged such that when piston 50 continues to move through the first stroke, the combustion phase ends (concurrent with exhaust phase beginning) before first opening 44 enters cylinder 12.
Following an expansion stroke portion (also called a combustion phase), piston 50 may continue to move in a momentum stroke portion for a remainder of the stroke. The momentum stroke portion of each stroke encompasses the remaining portion of the stroke following the expansion stroke portion. In accordance with embodiments of the disclosure, substantially the entire momentum stroke portion of the second stroke on the second combustion chamber side of piston 50 may coincide with compression of gases in the first combustion chamber. That is, the momentum that follows an expansion portion of the stroke in one combustion chamber may be used to compress gasses in the other combustion chamber. This may be made possible by an engine structure where an end of an expansion in one combustion chamber may correspond with a position different from the combustion position in an opposing combustion chamber. Such an engine design may enable further piston travel following an expansion portion of the stroke. In some embodiments, the further piston travel during the momentum portion of the stroke may be at least a width of the piston. A “width” of the piston may be synonymous with a length of the piston in the direction of axis A. In some embodiments the further piston travel may be multiple times a width of the piston. In other embodiments, the further piston travel may be a fraction of the width of the piston, for example at least a half a width of the piston. In yet other embodiments, the further travel may be at least a quarter a width of the piston. Further travel of piston 50 beyond at least one of exhaust ports 18 may be referred to as piston overshoot.
During the momentum stroke portion of each stroke, gases may be exchanged between the combustion chamber where ignition of combustion gases has just occurred and an area external to cylinder 12. The exchange of gases may occur through exhaust ports formed in peripheral wall 13 of cylinder 12. The exchange of gases may be aided by introduction of air into cylinder 12 through a passageway in the piston rod portion connected to the piston and extending from a location within the at least one combustion chamber to an area external to the cylinder. By way of one example with reference to
As combustion begins, piston 50 will move to the left. As shown in
As piston 50 continues to move to the left, piston 50 may reach a position where piston 50 has just passed the centrally located exhaust ports 18, as shown in
As shown in
Shortly after piston 50 has passed exhaust ports 18 during the momentum stroke portion of the stroke from the right end of cylinder 12 to the left end of cylinder 12, as shown in
Some aspects of the present disclosure may involve cylinder 12 and piston 50 being sized such that the expansion stroke portion of the first stroke on a first side of piston 50 as piston 50 moves from the first end of cylinder 12 to the second end of cylinder 12 coincides with at least one of a scavenging phase and a gas boost phase on a second side of piston 50. A similar coincidence may occur in connection with the second stroke. By way of non-limiting example with reference to the figures, as piston 50 continues to move toward the left end of the cylinder, as shown in
Some aspects of the present disclosure may involve cylinder 12 and piston 50 being sized such that the momentum stroke portion of the first stroke on a first side of piston 50 as piston 50 moves from the first end of cylinder 12 to the second end of cylinder 12 coincides with a compression phase in the combustion chamber on a second side of piston 50. By way of non-limiting example, simultaneously with the momentum stroke portion of the first stroke from the right end of cylinder 12 to the left end of cylinder 12, after piston 50 has moved past exhaust ports 18 toward the left end of cylinder 12, gases on the left side of piston 50 are compressed during a compression phase on the left side of piston 50. When piston 50 is all the way to the left, as shown in
As best seen by way of non-limiting example in
At the beginning of an expansion stroke portion of a stroke from the left end of cylinder 12 to the right end, as shown in
The length of piston 50, the length of cylinder 12, the location of exhaust ports 18, and the location of openings 44, 48 in each of the first and second piston rod portions 42, 43 extending from opposite faces of piston 50 may be arranged such that when piston 50 is in a combustion phase in second combustion chamber 73 on the left side of piston 50, piston 50 blocks exhaust ports 18 from communicating with second combustion chamber 73. Meanwhile, second opening 48 to the left side of piston 50 remains outside of second combustion chamber 73, thereby preventing communication of gases between inlet chamber 32 and second combustion chamber 73.
Simultaneously, exhaust ports 18 are in fluid communication with first combustion chamber 71 on the right side of piston 50, and first opening 44 in first piston rod portion 42 is located within first combustion chamber 71.
The momentum stroke portion of each stroke may encompass the remaining portion of the stroke following the expansion stroke portion. During the momentum stroke portion of each stroke, gases may be exchanged between the combustion chamber where ignition of combustion gases has just occurred and an area external to the cylinder. The exchange of gases may occur through exhaust ports formed in the peripheral wall of the cylinder.
As combustion begins in the second stroke, piston 50 will move to the right. As shown in
As the piston continues to move to the right, piston 50 may reach a position where piston 50 passes the centrally located exhaust ports 18, as shown in
As shown in
Shortly after piston 50 has passed exhaust ports 18 during the momentum stroke portion of the stroke from the left end of cylinder 12 to the right end of cylinder 12, as shown in
As the piston continues to move toward the right end of the cylinder, as shown in
In accordance with some embodiments of the present disclosure, regardless of other particular structures in the engine, a cylinder and a double-faced piston may be sized such that a total distance the piston travels during a first stroke is substantially greater than a distance the piston travels during an expansion stroke portion of the first stroke. By way of example with reference to
In some embodiments, a cylinder and a piston may be sized such that the total distance the piston travels during each stroke from one end of the cylinder to the opposite end of the cylinder may exceed the distance the piston travels during the expansion stroke portion of the stroke by at least the length of the piston from one face to the opposite face. In other exemplary embodiments, the cylinder and the piston may be sized such that a total distance the piston travels in each stroke exceeds, by at least the length of the piston, a distance traveled by the piston during compression of gases on one side of the piston. The length of piston 50 from one face to the opposite face in an exemplary embodiment shown in the figures may be less than ½ of a distance from at least one of cylinder heads 14, 15 to exhaust ports 18. This configuration and relative sizing of the piston and cylinder may allow for a significantly greater length of the total stroke for the piston in each direction during which fresh pre-compressed air or other gases may be introduced into the cylinder for the purposes of scavenging exhaust gases and cooling the cylinder after each combustion occurs at opposite ends of the cylinder.
In some embodiments, a cylinder and a piston may be configured such that an amount of overshoot of the piston after the end of an expansion phase may be substantially greater than the length of a compression volume. The compression volume may correspond to the clearance volume in cylinder 12 as discussed above. For example, piston 50 and cylinder 12 may be sized such that a length that piston 50 travels in a momentum stroke portion is substantially greater than the length of the clearance volume between one side of piston 50 and the closest cylinder head 14, 15 at the combustion position. In some embodiments, an amount of overshoot is at least a quarter the length of piston 50. Setting an amount of overshoot in this manner to be, for example, at least a quarter the length of piston 50, may be useful to ensure a sufficient duration for scavenging to occur in cylinder 12.
In accordance with some embodiments of the present disclosure, an internal combustion engine may include a piston kit being formed of an assembly of separate pieces, including a pair of piston rod portions and a piston comprising a disk. By way of example, and as shown in
Engine 10 may be provided with a single air supply. The single air supply may be connected to an inlet chamber. For example, in the embodiment as shown in
When a single air supply is provided, inlet chamber 32 may be configured to permit fresh air to flow into both first combustion chamber 71 and second combustion chamber 73. Furthermore, in some embodiments, first vestibule 30 and second vestibule 31 may be configured as isolation areas. An isolation area may be an area external to cylinder 12 that is configured to isolate non-active piston rod parts during alternate cylinder charges. For example, first vestibule 30 may act as a first isolation area on one side of cylinder 12 and second vestibule 31 may act as a second isolation area on an opposite side of cylinder 12.
In some embodiments, multiple air supplies may be provided. For example, rather than providing inlet chamber 32, engine 10 may include two air supplies, each configured to supply air to one of first vestibule 30 or second vestibule 31. Engine 10 may include a first air supply that communicates with first vestibule 30 and a second air supply that communicates with second vestibule 31, each through a respective side opening 33. The two air supplies may be connected upstream of side openings 33. Thus, a single air supply may be bifurcated to form multiple air supplies. In this embodiment, one or both of first piston rod portion 42 and second piston rod portion 43 may include occluded ends. In such cases, additional openings may be provided in first piston rod portion 42 and second piston rod portion 43. For example, a further set of openings may be provided on first piston rod portion 42 that is spaced apart from first opening 44. The further set of openings may be configured to communicate gas from first vestibule 30 while first opening is inside cylinder 12. The further set of openings may be configured to be outside cylinder 12 when first opening 44 is inside cylinder 12. A structure of the further set of opening may be similar to that of first openings 44. Such further set of openings may be similarly provided in second piston rod portion 43.
Flow of gases within piston kit 56 may occur in different directions. In some embodiments, a passageway in a piston assembly may be configured to communicate gas flow in a first direction from a first side of the piston to a second side of the piston, and to communicate gas flow in a second direction from the second side of the piston to the first side of the piston. For example, passageway 46 may be provided in piston rod 40, wherein passageway 46 is configured to allow gas flow in a first direction from area 67 on one side of piston 50 to the inside of cylinder 12 through second opening 48. Piston 50 may be at the first position, for example at the combustion position on the right side of cylinder 12 at the time of supplying gas to cylinder 12 through second opening 48. Passageway 46 may also be configured to allow gas flow in a second direction from area 65 on the opposite side of piston 50 to the inside of cylinder 12 through first opening 44. Piston 50 may be at the second position, for example at the combustion position on the left side of cylinder 12 at the time of supplying gas to cylinder 12 through first opening 44.
In some embodiments, flow of gases within piston kit 56 may be in the same direction. For example, when inlet chamber 32 is provided, gas may flow from inlet opening 29 through passageway 46 and into cylinder 12 via second opening 48 (see
A piston rod may be configured such that the piston assembly is slidable between a position where piston rod openings are blocked and a position where at least one of piston rod openings are opened. In some positions throughout the range of travel of piston 50, there may be positions where none of first opening 44 or second opening 48 is in fluid communication with cylinder 12. For example,
An engine in accordance with exemplary embodiments of the disclosure may produce further benefits. For example, an engine may facilitate nearly continuous scavenging of hot exhaust gases from the cylinder while continuously supplying fresh air for combustion. The nearly continuously introduced fresh pre-compressed air may decrease the temperature within the cylinder and increase the engine efficiency and engine service life.
Various alterations and modifications may be made to the disclosed exemplary embodiments without departing from the spirit or scope of the disclosure. For example, the burned gases produced by the engine 10 may be used for driving a turbo charger. The compressed air introduced into the cylinder may be pressurized by an external compressor that is driven by the reciprocating piston rod portions extending from opposite ends of the cylinder. Other variations may include imparting a swirl effect to the gases introduced into the cylinder by changing the angle of the inlet ports and of the outlet ports so that gases are not directed radially into or out of the cylinder.
To expedite the foregoing portion of the disclosure, various combinations of elements are described together. It is to be understood that aspects of the disclosure in their broadest sense are not limited to the particular combinations previously described. Rather, embodiments of the invention, consistent with this disclosure, and as illustrated by way of example in the figures, may include one or more of the following listed features, either alone or in combination with any one or more of the following listed features, or in combination with the previously described features.
For example, there may be provided a linear reciprocating engine. The engine may include a cylinder having a first combustion chamber at a first end thereof and a second combustion chamber at an opposing second end thereof; a first cylinder head located at an end of the first combustion chamber; a second cylinder head located at an end of the second combustion chamber; a piston slidably mounted within the cylinder; and a piston rod including at least one piston rod portion extending through the first combustion chamber and the second combustion chamber, the at least one piston rod portion having at least one first port located on a first side of the piston and at least one second port located on a second side of the piston, opposite the first side of the piston. There may also be provided the following elements:
Furthermore, for example, there may be provided a linear reciprocating engine including a cylinder having a first combustion chamber at a first end thereof and a second combustion chamber at an opposing second end thereof; a vestibule located external to the first combustion chamber proximate the first end; a piston slidably mounted within the cylinder; a first piston rod portion extending from the piston through the first combustion chamber and into the vestibule, the first piston rod portion including a hollow tube portion having an inlet port and at least one first sidewall opening therein; and a second piston rod portion extending from the piston through the second combustion chamber, the second piston rod portion having a hollow tube portion and at least one second sidewall opening therein. There may also be provided the following elements:
Furthermore, for example, there may be provided a linear reciprocating engine including a cylinder having a first combustion chamber at a first end thereof and a second combustion chamber at an opposing second end thereof; a first vestibule located external to the first combustion chamber proximate the first end; a second vestibule located external to the second combustion chamber proximate the second end; a piston slidably mounted within the cylinder; a first piston rod portion extending from the piston through the first combustion chamber and into the first vestibule, the first piston rod portion having a first elongated passageway portion therethrough and at least one first port therein; and a second piston rod portion extending from the piston through the second combustion chamber and into the second vestibule, the second piston rod portion having a second elongated passageway portion therethrough and at least one second port therein. There may also be provided the following elements:
Furthermore, for example, there may be provided an internal combustion engine including a cylinder having a first combustion chamber at a first end thereof and a second combustion chamber at an opposing second end thereof; a vestibule external to the combustion chamber; a piston slidably mounted within the cylinder; and a piston rod extending from the piston through the combustion chamber and into the vestibule. There may also be provided the following elements:
Furthermore, for example, there may be provided a linear reciprocating engine including a cylinder having a first combustion chamber at a first end thereof and a second combustion chamber at an opposing second end thereof, the cylinder having one or more side ports therein; a first cylinder head located at an end of the first combustion chamber; a second cylinder head located at an end of the second combustion chamber; a double-faced piston slidably mounted within the cylinder; a first piston rod portion extending from the piston through the first combustion chamber and into a first pressurizable vestibule, the first piston rod portion having a first elongated passageway portion therethrough and at least one first port therein; a second piston rod portion extending from the piston through the second combustion chamber and into a second pressurizable vestibule, the second piston rod portion having a second elongated passageway portion therethrough, the second elongated passageway portion being flow connected to the first elongated passageway and at least one second port therein. There may also be provided the following elements:
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
1040472, | |||
1707035, | |||
1720504, | |||
1755673, | |||
1764815, | |||
1796882, | |||
2028331, | |||
2187979, | |||
2392052, | |||
2399683, | |||
2407790, | |||
2831738, | |||
2874012, | |||
3146940, | |||
3358656, | |||
3365879, | |||
3369733, | |||
3465161, | |||
3610217, | |||
3791227, | |||
3797466, | |||
3914574, | |||
4156410, | Jul 18 1977 | Ran-Z, Inc. | Internal combustion reciprocating engine |
4385597, | Aug 01 1980 | Two-stroke internal combustion engine | |
4414927, | Apr 16 1982 | Two stroke oscillating piston engine | |
4489554, | Jul 09 1982 | Variable cycle stirling engine and gas leakage control system therefor | |
4653274, | Mar 06 1984 | Method of controlling a free piston external combustion engine | |
4658768, | Dec 28 1981 | Engine | |
4803960, | Jun 01 1987 | Internal combustion engine, particularly, a free-piston engine | |
4831972, | May 04 1988 | Internal combustion engine | |
4854218, | Oct 05 1985 | Piston and cylinder unit | |
4876991, | Dec 08 1988 | GALILEO RESEARCH, INC | Two stroke cycle engine |
5123245, | Oct 19 1990 | Sampower Oy | Method and apparatus for starting a free piston combustion engine hydraulically |
5158046, | Oct 02 1991 | Two-stroke cycle engine having linear gear drive | |
5285752, | Apr 23 1993 | Single-Stroke Motors, Inc. | Internal combustion engine |
5351659, | Dec 14 1993 | Shaft engine | |
5676097, | Sep 22 1995 | High-efficiency explosion engine provided with a double-acting piston cooperating with auxiliary feed inlet units | |
5710514, | May 09 1995 | Mid-America Commercialization Corporation | Hydraulic cylinder piston position sensing with compensation for piston velocity |
5816202, | Sep 22 1995 | High efficiency explosion engine with a double acting piston | |
6035637, | Jul 01 1997 | SUNPOWER, INC | Free-piston internal combustion engine |
6065438, | Dec 23 1997 | Caterpillar Inc. | Continuous piston rings for an internal combustion engine |
6164250, | Feb 22 1999 | Caterpillar Inc. | Free piston internal combustion engine with piston head having a radially moveable cap |
6170442, | Jul 01 1997 | SUNPOWER, INC | Free piston internal combustion engine |
6199519, | Jun 25 1998 | National Technology & Engineering Solutions of Sandia, LLC | Free-piston engine |
6240828, | Apr 21 1998 | NISSAN MOTOR CO , LTD | Piston of internal combustion engine |
6298941, | Jan 29 1999 | Dana Corporation | Electro-hydraulic power steering system |
6467397, | Jan 20 1999 | Mahle GmbH | Constructed piston or piston consisting of components that are welded or soldered together |
6722322, | Apr 17 2002 | Internal combustion engine | |
6948459, | Aug 28 2004 | Ford Global Technologies, LLC | Position sensing for a free piston engine |
7032548, | Jun 28 2004 | Ford Global Technologies, LLC | Piston guides for a free piston engine |
7194989, | Mar 03 2005 | Energy efficient clean burning two-stroke internal combustion engine | |
7207299, | Mar 15 2002 | ADVANCED PROPULSION TECHNOLOGIES, INC | Internal combustion engine |
7318506, | Sep 19 2006 | Free piston engine with linear power generator system | |
7412949, | Mar 14 2007 | James A., Cillessen | Dual head piston engine |
9010287, | Mar 14 2014 | Multi-fuel engine | |
9206900, | Feb 18 2011 | Cool Energy, Inc. | Assembly for sealing a sliding interface |
20020189433, | |||
20040244765, | |||
20050284426, | |||
20060157003, | |||
20060232268, | |||
20070017684, | |||
20080251050, | |||
20090114391, | |||
20110073419, | |||
20110239642, | |||
20120160190, | |||
20120192438, | |||
20120266842, | |||
20120280513, | |||
20130276740, | |||
20130298874, | |||
20140116389, | |||
20150114352, | |||
20160208686, | |||
20170016327, | |||
20170044975, | |||
20180106215, | |||
DE102008004879, | |||
DE202006018097, | |||
DE3149930, | |||
DE3347859, | |||
DE3518982, | |||
DE4136331, | |||
DE4447040, | |||
FR1437474, | |||
GB2183726, | |||
GB2232718, | |||
GB2353562, | |||
GB337248, | |||
GB602310, | |||
JP6238833, | |||
JP63192916, | |||
RU2500905, | |||
WO2015155912, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 27 2020 | Aquarius Engines (A.M.) Ltd. | (assignment on the face of the patent) | / | |||
Nov 12 2020 | SHAUL HAIM YAAKOBY | AQUARIUS ENGINES A M LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 054347 | /0340 |
Date | Maintenance Fee Events |
Mar 27 2020 | BIG: Entity status set to Undiscounted (note the period is included in the code). |
Apr 07 2020 | SMAL: Entity status set to Small. |
Sep 18 2024 | M2551: Payment of Maintenance Fee, 4th Yr, Small Entity. |
Date | Maintenance Schedule |
Apr 06 2024 | 4 years fee payment window open |
Oct 06 2024 | 6 months grace period start (w surcharge) |
Apr 06 2025 | patent expiry (for year 4) |
Apr 06 2027 | 2 years to revive unintentionally abandoned end. (for year 4) |
Apr 06 2028 | 8 years fee payment window open |
Oct 06 2028 | 6 months grace period start (w surcharge) |
Apr 06 2029 | patent expiry (for year 8) |
Apr 06 2031 | 2 years to revive unintentionally abandoned end. (for year 8) |
Apr 06 2032 | 12 years fee payment window open |
Oct 06 2032 | 6 months grace period start (w surcharge) |
Apr 06 2033 | patent expiry (for year 12) |
Apr 06 2035 | 2 years to revive unintentionally abandoned end. (for year 12) |